JP2016509243A - Arrangement for inspecting electronic device overheat protection device and inspection method thereof - Google Patents

Abstract

The present invention relates to an arrangement and inspection method for inspecting a device for protecting an electronic element (6) from overheating. The device (1) comprises a temperature sensor (2) thermally connected to the electronic element (6) and a first control circuit (4) for the electronic element (6). The temperature sensor (2) is electrically connected to the first control circuit (4). The arrangement comprises a heating element (3) thermally connected to the temperature sensor (2), which can be controlled by a second control circuit (7). [Selection] Figure 2

Description

  The present invention relates to an arrangement for inspecting a device for protecting an electronic element from overheating and an inspection method thereof.

  When the semiconductor integrated circuit is movable, at least a part of the electric power is converted into heat. For example, under certain conditions such as overload, short circuit, and external heating of the semiconductor chip, such heat may cause undesirably overtemperature. In order to protect the semiconductor integrated circuit by detecting such an overtemperature, the semiconductor integrated circuit is usually provided with a thermal protection device. However, such a thermal protection device must meet various requirements.

  For example, in a circuit arrangement including a circuit breaker that switches a load current, such as a DC motor or an asynchronous motor, a short circuit may occur in the load circuit, which may destroy the circuit breaker or the switched load current itself. These circuit arrangements are equipped with one or more temperature sensors to protect the circuit breaker, the temperature sensor signal is evaluated by the evaluation circuit and a short circuit occurs, resulting in a significant temperature in the circuit breaker. When is raised, the circuit breaker is turned off. If the predetermined temperature threshold is exceeded, the circuit breaker is turned off, thereby protecting it from breakage. The temperature sensor is usually configured as a resistor, diode or transistor sensor and is preferably integrated in the vicinity of the corresponding hot spot, i.e. the hottest position of the circuit breaker. Then, the evaluation circuit processes the temperature sensor signal, and the temperature acting on the temperature sensor depends on each application case, but exceeds a predetermined temperature threshold, which is usually above 150 ° C, The circuit breaker is immediately turned off or at least the power is reduced.

  German Patent Specification 10107386C1 discloses an arrangement for protecting an integrated circuit from over temperature. This arrangement includes at least one detector that detects a fault in the integrated circuit, at least one temperature sensor that detects the temperature of at least a portion of the integrated circuit, logic that determines the problem operation by the detected fault and / or the detected temperature. In the normal operation, the first temperature switching stage HTL is assigned to the temperature sensor, and in problem operation, the second, lower temperature switching stage is assigned to the temperature sensor. The German patent specification 10107386C1 further discloses an integrated circuit with such an arrangement and a method for protecting the integrated circuit from over temperature.

  European Patent Specification No. 0208970B1 discloses a circuit arrangement that protects a circuit breaker from overheating. In order to protect the power MOSFET in the event of an overtemperature, a temperature sensor switch and a second semiconductor substrate including the semiconductor switch are bonded onto the semiconductor substrate including the power MOSFET. Both semiconductor substrates are thermally coupled to each other so that overtemperature of the power MOSFET in the semiconductor substrate can be detected. For example, an electronic switch in the second semiconductor substrate, which is a thyristor, conducts between the source electrode and the drain electrode. When the internal temperature of the MOSFET rises due to overload or high ambient temperature, the electronic switch included in the second semiconductor substrate short-circuits the MOSFET gate electrode with respect to the source electrode. The voltage acting between the gate electrodes collapses and the MOSFET is turned off.

  A disadvantage of the circuit arrangement known from the prior art is that the function of the temperature sensor cannot be tested in normal operation.

German patent specification 10107386C1 European Registered Patent Specification No. 0208970B1

  An object of the present invention is to propose a circuit capable of inspecting a temperature sensor and a circuit connected to the temperature sensor in order to protect the electronic element from overheating. A further challenge is to propose the method.

  This problem is solved by the arrangement with the features of independent claim 1 and the features of claim 4. Advantageous embodiments of the invention are the subject of the dependent claims.

  The present invention is based on a device for protecting electronic elements from overheating. The electronic element can be, for example, a control means, or a transmission control means for a vehicle, for example. Such devices include a temperature sensor, which is in thermal connection or contact with the electronic element. This thermal connection can be realized, for example, by mounting a temperature sensor on the electronic element 6 with a heat conductive adhesive. The electronic element can also be a semiconductor mounted on a circuit board, in which case the temperature sensor can also be thermally connected or contacted with the circuit board. Thus, an “electronic device” can also be understood on the one hand as any kind of semiconductor substrate that generates heat, for example as an integrated circuit or a transistor, and as a supporting substrate, for example a circuit substrate, for supporting such a semiconductor substrate.

  The electronic element is connected to the first control circuit. The control circuit can be a microcontroller that substantially controls the current and voltage supply of the electronic device. However, the control circuit can receive and process signals and / or data generated by the electronic elements. The temperature sensor is electrically connected to the first control circuit so that the first control circuit can receive and process temperature sensor signals and data.

  According to the invention, a heating element is provided which is thermally connected to the temperature sensor. Thermal connection can be achieved, for example, by mounting the heating element on the temperature sensor using a thermally conductive adhesive. However, it is also possible to integrate this heating element into the temperature sensor. The heating element is connected to the second control circuit, and the second control circuit controls the current and voltage supply of the heating element.

  A preferred embodiment of the present invention includes a storage means for a temperature rise curve of the temperature sensor. Suitably, the first control circuit is adjusted to be able to store a temperature dependent signal transmitted from the temperature sensor to the first control circuit.

  A further preferred embodiment of the invention comprises means for checking the switch state of the electronic element. Suitably the first control circuit is adjusted such that the operating state of the electronic element can be determined.

According to the present invention, a method for inspecting an apparatus for protecting an electronic element from overheating comprising
a) providing an apparatus for protecting an electronic element, the apparatus comprising a temperature sensor and a temperature sensor in thermal communication with the electronic element;
b) providing a heating element in thermal connection with the temperature sensor;
c) heating the temperature sensor to a target temperature with a heating element;
d) comparing the target temperature of the temperature sensor with the actual temperature;
e) turning off the electronic device when the actual temperature of the temperature sensor exceeds the target temperature.

Suitably, the step of heating the temperature sensor to the target temperature in step d) can be performed during operation of the electronic element. Steps c), d) and e) can be performed at different time intervals during the operation of the circuit or electronic element whose overheating is to be monitored. Of course, the steps of the method can also be carried out during the activation process of the electronic element, in other words at turn-on.

The present invention will be described in further detail with reference to the drawings.
FIG. 3 is a diagram of a basic circuit arrangement with an overheat protection device. 1 is a diagram of a general embodiment of a thermal protection circuit.

  FIG. 1 shows a basic circuit arrangement with an arrangement that protects the circuit arrangement from overheating. In FIG. 1, the circuit arrangement is indicated by reference numeral 1. The circuit arrangement 1 includes an electronic element 6. The electronic element 6 is, for example, a power circuit or a semiconductor element, and generates heat through power consumption during operation. Of course, the electronic element 6 can be a circuit board including a plurality of electronic elements 6.

  Suitably, the circuit arrangement 1 is provided with a temperature sensor 2 directly thermally connected to the electronic element 6 in the immediate vicinity. The temperature sensor 2 is mounted on the electronic element 6 by a heat conductive connection such as a heat conductive adhesive. However, the temperature sensor 2 can also be disposed inside the electronic element 6, in other words, can be integrated in the electronic element 6.

  Furthermore, the circuit arrangement 1 includes first control means 4. The first control means 4 is connected to the temperature sensor 2. The control means is further connected to a current and voltage supply 5 for the electronic element 6. In this case, the control means 4 is configured so that the temperature evaluation measured by the temperature sensor 2 can be stored. Furthermore, the control means 4 is configured to interrupt the current and voltage supply 5 for the electronic element 6 when the measured temperature exceeds a threshold, thereby preventing the electronic element 6 from being further overheated. ing.

  The circuit arrangement 1 further comprises a heating element 3. The heating element 3 is in thermal contact with the temperature sensor 2. The heating element 3 can be integrated with the temperature sensor. It is also possible to integrate the heating element 3, the temperature sensor 2 and the electronic element 6 into one component.

  The heating element 3 is connected to the second control means 7. The second control means 7 is configured to supply current and voltage to the heating element 3. Suitably, the second control means 7 and the first control means 4 can constitute individual control means.

  FIG. 2 shows a general embodiment of a thermal protection circuit. The configuration and function will be described in further detail with respect to this embodiment.

  The configuration of this embodiment substantially corresponds to the configuration of the embodiment shown in FIG. The heating element 3 is thermally connected to the temperature sensor 2.

  The temperature sensor 2 measures, for example, a temperature that rises through self-heating and / or external heating of the electronic element 6 that is a power circuit. The comparator 9 compares the temperature of the temperature sensor 2 with a threshold value of, for example, 130 ° C. of the threshold value generating means 8. This threshold value generating means 8 can also be integrated with the control means 4. If the temperature exceeds the threshold, the comparator 9 turns off the power circuit 6 via the transistor 10 to protect the circuit 1 from overheating. Thereafter, the circuit 6 can be cooled again until the temperature of the temperature sensor 2 falls below the threshold value of the threshold value generating means 8 again. Then, the comparator 9 turns on the power circuit 6 again through the transistor 10. The turn-off in this case is executed by interrupting the current and voltage supply unit 5 with respect to the power circuit 6.

  The comparator 9 usually has hysteresis.

  For example, the actual temperature and the switching threshold can be measured via the AD converter input units 13 and 14 of the first control means 4 which is a microcontroller. The microcontroller 4 can then check whether the power circuit 6 has been turned off via the AD converter input 15 of the microcontroller 4. If not turned off, the microcontroller 4 can additionally turn off the power circuit 6 via the transistor 11.

  The turn-off of the power circuit 6 can be canceled via the second control means 7 of the heating element 3. In FIG. 2, the second control means 7 is integrated with the first control means 4 which is a microcontroller. The output unit 12 of the microcontroller 4 further controls the transistor 17 to which the heating element 3 is connected. The heating element 3 heats the temperature sensor 2 to a predetermined temperature which is 130 ° C., for example. When the comparator 9 detects that the temperature of the temperature sensor 2 exceeds the threshold value of the threshold value generation means 8, the comparator 9 turns off the power circuit 6 via the transistor 10. This turn-off can be controlled by the AD converter input unit 15 of the microcontroller 4. When it is detected that the power circuit 6 is not turned off via the input unit 15, current and voltage supply for the power circuit 6 is provided via the output unit 16 of the microcontroller 4 and the transistor 11 as described above. Part 5 is additionally turned off.

  The temperature rising curve of the temperature sensor 2 when the heating element 3 is turned on is recorded via the input unit 14 of the microcontroller 4, and this temperature rising curve can be checked in light of the validity. For example, it can be checked whether the temperature sensor 2 reaches a predetermined temperature in a fixed time window.

DESCRIPTION OF SYMBOLS 1 Circuit arrangement | positioning 2 Temperature sensor 3 Heating element 4 1st control means 5 Current and voltage supply part 6 Electronic element 7 2nd control means 8 Threshold generation means 9 Comparator 10 Transistor 11 Transistor 12 Output part 13 to heating element of control means 13th 1 Input unit 14 to threshold generation unit of control unit 15 Input unit 15 to temperature sensor of first control unit 15 Check input unit 16 Turn-off output unit 17 Transistor

Claims (4)

  An arrangement for inspecting a device that protects the electronic element (6) from overheating, the device (1) comprising: a temperature sensor (2) thermally connected to the electronic element (6) and the electronic element ( 6), wherein the temperature sensor (2) is electrically connected to the first control circuit (4), wherein the temperature sensor (2) is electrically connected to the temperature sensor (2). And a heating element (3) thermally connected to the heating element (3), the heating element (3) being controllable by a second control circuit (7).   Arrangement according to claim 1, characterized in that it comprises storage means (4, 14) for the temperature rise curve of the temperature sensor (2).   Arrangement according to claim 1 or 2, characterized in that it comprises means (4, 15) for checking the switch state of the electronic element (6). A device inspection method for protecting an electronic element (6) from overheating comprising:
Providing a device for protecting the electronic element (6), the device comprising a temperature sensor (2) and a temperature sensor (2) thermally connected to the electronic element (6); When,
Providing a heating element (3) in thermal connection with the temperature sensor (2);
Heating the temperature sensor (2) to a target temperature by the heating element;
Comparing the target temperature of the temperature sensor (2) with an actual temperature;
Turning off the electronic element (6) when the actual temperature of the temperature sensor (2) exceeds the target temperature;
Including methods.

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